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09/12/02 (C) 2002, University of Wisconsin, CS 559 Last Time Color and Color Spaces –Recall RGB and XYZ Programming assignment 2.

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Presentation on theme: "09/12/02 (C) 2002, University of Wisconsin, CS 559 Last Time Color and Color Spaces –Recall RGB and XYZ Programming assignment 2."— Presentation transcript:

1 09/12/02 (C) 2002, University of Wisconsin, CS 559 Last Time Color and Color Spaces –Recall RGB and XYZ Programming assignment 2

2 09/12/02 (C) 2002, University of Wisconsin, CS 559 Today More color spaces Image file formats –GIF –JPEG Intro to color quantization

3 09/12/02 (C) 2002, University of Wisconsin, CS 559 The RGB Color Matching Functions

4 09/12/02 (C) 2002, University of Wisconsin, CS 559 Computing the Matching The spectrum function that we are trying to match, E( ), gives the amount of energy at each wavelength The RGB matching functions describe how much of each primary is needed to match one unit of energy at each wavelength Hence, if the “color” due to E( ) is E, then the match is:

5 09/12/02 (C) 2002, University of Wisconsin, CS 559 Going from RGB to XYZ These are linear color spaces, related by a linear transformation Match each primary, for example: Substitute and equate terms:

6 09/12/02 (C) 2002, University of Wisconsin, CS 559 Standard RGB↔XYZ Note that each matrix is the inverse of the other Recall, Y encodes brightness, so the matrix tells us how to go from RGB to grey

7 09/12/02 (C) 2002, University of Wisconsin, CS 559 Determining Gamuts Gamut: The range of colors that can be represented or reproduced Plot the matching coordinates for each primary. eg R, G, B Region contained in triangle (3 primaries) is gamut Really, it’s a 3D thing, with the color cube distorted and embedded in the XYZ gamut x y XYZ Gamut RGB Gamut G R B

8 09/12/02 (C) 2002, University of Wisconsin, CS 559 Accurate Color Reproduction High quality graphic design applications, and even some monitor software, offers accurate color reproduction A color calibration phase is required: –Fix the lighting conditions under which you will use the monitor –Fix the brightness and contrast on the monitor –Determine the monitor’s γ –Using a standard color card, match colors on your monitor to colors on the card: This gives you the matrix to convert your monitor’s RGB to XYZ –Together, this information allows to to accurately reproduce a color specified in XYZ format (and hence any other standard format)

9 09/12/02 (C) 2002, University of Wisconsin, CS 559 More linear color spaces Monitor RGB: primaries are monitor phosphor colors, primaries and color matching functions vary from monitor to monitor sRGB: A new color space designed for web graphics YIQ: mainly used in television –Y is (approximately) intensity, I, Q are chromatic properties –Linear color space; hence there is a matrix that transforms XYZ coords to YIQ coords, and another to take RGB to YIQ –I and Q can be transmitted with low bandwidth

10 09/12/02 (C) 2002, University of Wisconsin, CS 559 HSV Color Space (Alvy Ray Smith, 1978) Hue: the color family: red, yellow, blue… Saturation: The purity of a color: white is totally unsaturated Value: The intensity of a color: white is intense, black isn’t Space looks like a cone –Parts of the cone can be mapped to RGB space Not a linear space, so no linear transform to take RGB to HSV –But there is an algorithmic transform

11 09/12/02 (C) 2002, University of Wisconsin, CS 559 HSV Color Space HSV Color Cone Program

12 09/12/02 (C) 2002, University of Wisconsin, CS 559 Uniform Color Spaces Color spaces in which distance in the space corresponds to perceptual “distance” Only works for local distances –How far is red from green? Is it further than red from blue? Use MacAdams ellipses to define perceptual distance

13 09/12/02 (C) 2002, University of Wisconsin, CS 559 MacAdam Ellipses Scaled by a factor of 10 and shown on CIE xy color space If you are shown two colors inside the same ellipse, you cannot tell them apart Only a few ellipses are shown, but one can be defined for every point

14 09/12/02 (C) 2002, University of Wisconsin, CS 559 Violet CIE u’v’ Space CIE u’v’ is a non-linear color space where color differences are more uniform Note that now ellipses look more like circles The third coordinate is the original Z from XYZ

15 09/12/02 (C) 2002, University of Wisconsin, CS 559 Subtractive mixing Inks subtract light from white, whereas phosphors glow Common inks: Cyan=White−Red, Magenta=White−Green, Yellow=White−Blue –For example, to make a red mark, put down magenta and yellow, which removes the green and blue leaving red For a good choice of inks, matching is linear: –C+M+Y=White-White=Black –C+M=White-Red-Green=Blue Usually require CMY and Black, because colored inks are more expensive, and registration is hard

16 09/12/02 (C) 2002, University of Wisconsin, CS 559 Calibrating a Printer If the inks (think of them as primaries) are linear, there exists a 3x3 matrix and an offset to take RGB to CMY –For example, of RGB of (1,0,0) goes to CMY of (0,1,1); (0,1,0)→(1,0,1); and (0,0,1)→(1,1,0), then the matrix is To calibrate your printer, you find out exactly what the numbers in the matrix should be

17 09/12/02 (C) 2002, University of Wisconsin, CS 559 Image File Formats How big is the image? –All files in some way store width and height How is the image data formatted? –Is it a black and white image, a grayscale image, a color image, an indexed color image? –How many bits per pixel? What other information? –Color tables, compression codebooks, creator information…

18 09/12/02 (C) 2002, University of Wisconsin, CS 559 The Simplest File Assumes that the color depth is known and agreed on Store width, height, and data for every pixel in sequence This is how you normally store an image in memory Unsigned because width and height are positive, and unsigned char because it is the best type for raw 8 bit data Note that you require some implicit scheme for laying out a rectangular array into a linear one class Image { unsigned int width; unsigned int height; unsigned char *data; } 3 r,g,b 0r0r 0 r,g,b 1 r,g,b 2 r,g,b 4 r,g,b 5 r,g,b 8 r,g,b 7 r,g,b 6 r,g,b 0g0g 0b0b 1g1g 1r1r 1b1b 2r2r 2g2g 2b2b 3r3r 3g3g

19 09/12/02 (C) 2002, University of Wisconsin, CS 559 Indexed Color 24 bits per pixel (8-red, 8-green, 8-blue) are expensive to transmit and store It must be possible to represent all those colors, but not in the same image Solution: Indexed color –Assume k bits per pixel (typically 8) –Define a color table containing 2 k colors (24 bits per color) –Store the index into the table for each pixel (so store k bits for each pixel) –Once common in hardware, now rare (256 color displays)

20 09/12/02 (C) 2002, University of Wisconsin, CS 559 Indexed Color Color Table 0 1 2 3 4 5 6 7 4302 1745 3765 2211 Pixel DataImage Only makes sense if you have lots of pixels and not many colors

21 09/12/02 (C) 2002, University of Wisconsin, CS 559 Image Compression Indexed color is one form of image compression –Special case of vector quantization Alternative 1: Store the image in a simple format and then compress with your favorite compressor –Doesn’t exploit image specific information –Doesn’t exploit perceptual shortcuts Two historically common compressed file formats: GIF and JPEG –GIF should now be replaced with PNG, because GIF is patented and the owner started enforcing the patent

22 09/12/02 (C) 2002, University of Wisconsin, CS 559 GIF Header – Color Table – Image Data – Extensions Header gives basic information such as size of image and size of color table Color table gives the colors found in the image –Biggest it can be is 256 colors, smallest is 2 Image data is LZW compressed color indices To create a GIF: –Choose colors –Create an array of color indices –Compress it with LZW

23 09/12/02 (C) 2002, University of Wisconsin, CS 559 LZW Compression Compresses a stream of “characters”, in GIF case they are 1byte color indices Stores the strings encountered in a codebook –When compressing, strings are put in the codebook the second time they are encountered –Subsequent encounters replace the string with the code –Decoding reconstructs codebook on the fly –Advantage: The code does not need to be transmitted

24 09/12/02 (C) 2002, University of Wisconsin, CS 559 JPEG Multi-stage process intended to get very high compression with controllable quality degradation Start with YIQ color –Why? Recall, it’s the color standard for TV

25 09/12/02 (C) 2002, University of Wisconsin, CS 559 Discrete Cosine Transform A transformation to convert from the spatial to frequency domain – done on 8x8 blocks Why? Humans have varying sensitivity to different frequencies, so it is safe to throw some of them away Basis functions:

26 09/12/02 (C) 2002, University of Wisconsin, CS 559 Quantization Reduce the number of bits used to store each coefficient by dividing by a given value –If you have an 8 bit number (0-255) and divide it by 8, you get a number between 0-31 (5 bits = 8 bits – 3 bits) –Different coefficients are divided by different amounts –Perceptual issues come in here Achieves the greatest compression, but also quality loss “Quality” knob controls how much quantization is done

27 09/12/02 (C) 2002, University of Wisconsin, CS 559 Entropy Coding Standard lossless compression on quantized coefficients –Delta encode the DC components –Run length encode the AC components Lots of zeros, so store number of zeros then next value –Huffman code the encodings

28 09/12/02 (C) 2002, University of Wisconsin, CS 559 Lossless JPEG With Prediction Predict what the value of the pixel will be based on neighbors Record error from prediction –Mostly error will be near zero Huffman encode the error stream Variation works really well for fax messages

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